Electronics Module and Arrangement for a Ventricular Assist Device, and Method for Producing a Ventricular Assist Device

BACKGROUND

Field

The invention relates to an electronics module and an arrangement for a ventricular assist device and to methods for producing a ventricular assist device.

Description of the Related Art

Larger ventricular assist devices, such as implanted left ventricular assist devices, can have sensors whose electronics can be constructed, for example, on circuit boards and integrated into correspondingly large cavities of the device. Smaller, fully implanted devices, also called percutaneous assist devices, have high requirements for the installation size, so that integration of additional electronics is generally dispensed with in this case.

SUMMARY

The object of the invention is to provide an electronics module and an arrangement for a ventricular assist device as well as a production method for a ventricular assist device, which allows the integration of electronic assemblies and sensors into the ventricular assist device, in particular in a percutaneous left ventricular assist device, in a small installation space.

This object is achieved by an electronics module, arrangement, and production method specified in the present disclosure. Advantageous embodiments of the invention are specified in the dependent claims.

The invention is based on the idea that sensors and other electronic components, such as microcontrollers or conductor structures, can be integrated into a percutaneous left ventricular assist device by means of a suitably shaped pump housing component. For this purpose, the pump housing component is realized from at least two housing parts so that the electronics can be constructed in the first housing part, the motor can be constructed in the second housing part, and the housing parts can then be joined together to form a complete motor. The electronics can be placed inside the pump housing component or in depressions on its outside. The latter is particularly useful for sensors. For example, the pump housing component can be manufactured, at least in sections, from ceramics with integrated conductor structures. Such a ceramic component can be constructed, for example, as an injection-molded part, in an additive layer construction, e.g., by 3D printing, or by laminating two-dimensional ceramic substrates.

The approach presented here thus allows the hermetic closure of the motor by a so-called backend, the production of a hermetically sealed electrical contacting from the inside of the motor to the outside, the joining together of electrical conductors from the inside of the motor with a sensor cable laid on the outside of the motor or a connection cable, the integration of electronics into a percutaneous ventricular assist device as an integral component of the housing components, and the integration of sensor technology, e.g., a blood pressure, acceleration, vibration, body-borne sound, temperature, Hall, ultrasonic, surface acoustic wave, optical, or biochemical sensor, or a microphone, at the proximal end of the ventricular assist device.

Particularly advantageous is the possible integration of a microcontroller as a processing unit into the proximal end for aggregating sensor data, storing calibration data, identification via a serial number, or for realizing a transceiver function.

The backend can be electrically functionalized, for example, via a 3D-MID ceramic structure.

The strands of the motor windings can be contacted directly to the ceramic by means of optional contact surfaces inside, which eliminates the need for additional rewiring.

In particular, the approach presented here allows an integration of electronics inside a hermetically sealed environment so that only sensors that are necessarily to be exposed come into contact with blood in the non-hermetic region, which increases biocompatibility and reliability.

For example, a sensor hub in the form of a microcontroller for the preprocessing of sensor data, translation of a communication protocol, redundancy and error protection of a transmission path, or identification of a pump can be integrated in this way.

When ceramics are used, conductor paths and electronic components can be directly applied to a starting material without additional insulation layers due to the insulating properties of ceramics. Short circuits can also not occur at the contacting sites, e.g., via pins for connecting sensors or hybrid cables. In addition, the thermal insulation properties of ceramics allow decoupling of measurements of an ambient temperature from the motor heat.

An electronics module for a ventricular assist device is presented, wherein the ventricular assist device has a motor housing for accommodating a pump motor, wherein the electronics module has the following features:

•

• an electronics section for accommodating at least one electronic component and/or at least one electrically conductive contacting element; and • a coupling section, which is designed as a joint between the motor housing and the electronics section or as a separate component to be joined, wherein the motor housing and the electronics section are combined or can be combined via the coupling section to form a fluid-tight module housing to be arranged in a blood vessel.

An electronics module can be understood to mean a unit that is designed for electrical contacting and/or accommodating circuit, control, or sensor technology. A ventricular assist device, also called artificial heart or VAD (ventricular assist device), can be understood to mean a pumping device for increasing the pump performance of a heart. The ventricular assist device can be insertable into a heart chamber or into the aorta by means of a catheter, for example. The ventricular assist device may in particular be a left ventricular assist device. The module housing can be a housing component of the ventricular assist device. A coupling section can be understood to mean a first housing part of the module housing. An electronics section can be understood to mean a second housing part of the module housing. Alternatively, the coupling section can also be a partial region or a surface of the electronics module. The module housing can be connected or connectable, e.g., by welding, to the motor housing to form a hermetically sealed housing unit. The coupling section and the electronics section can be connected to one another in a fluid-tight manner by means of an adhesive bond or by using an additional sealing element, for example. The coupling section can also be designed as a surface coating or partial section of a surface of the electronics section at the joint or as an adhesive bead. An electronic component can be understood to mean a microcontroller, a sensor element, or another electronic component, in particular a semiconductor-based component, for example. A contacting element can be understood to mean a conductor path, a conductor path structure, a pin, e.g., for through-plating, or a pad, for example.

The electronics section can, for example, be largely made of an electrically insulating material. In particular, the contacting element can be embedded in the electrically insulating material, at least in sections. A blood vessel can be understood to mean an artery, vein, or a heart chamber, for example. The electronics module can also be referred to as the backend of the ventricular assist device and be arranged at a proximal end of the ventricular assist device.

According to one embodiment, the coupling section can be realized as a titanium part or titanium element and/or a sintered part or sintered element. Additionally or alternatively, the electronics section can be realized as a ceramic part or ceramic element and/or a layer composite of at least two layers. This makes it possible, on the one hand, to easily combine the module housing with the motor housing, e.g., by welding, and on the other hand to integrate the electronic component or the contacting element into the electronics section in an easy and space-saving manner. This can also improve the material compatibility or biocompatibility of the electronics module.

For example, the layers can be stacked one on top of the other in the longitudinal direction of the electronics section. As a result, the electronics section can be manufactured particularly efficiently, e.g., in an additive manufacturing process such as 3D printing.

According to another embodiment, the coupling section can be a surface layer or a partial section of the electronics section, which produces advantageous properties for joining to the motor housing.

According to another embodiment, the electronics module can be directly connectable or connected to the motor housing, e.g., by adhesive bonding.

According to another embodiment, the coupling section can be welded or weldable to the motor housing. This allows a particularly reliable hermetic sealing of the module housing with respect to the motor housing to be achieved and the established standard manufacturing processes to be used.

The coupling section can be annular. As a result, the coupling section can be manufactured particularly easily.

According to another embodiment, the coupling section and/or the electronics section can be cylindrical. As a result, the electronics module can be realized particularly advantageously with respect to a low risk of thrombosis.

Depending on the embodiment, the electronics module can have the electronic component and/or the contacting element. In this case, the contacting element can be designed to allow electrically conductive contacting between the electronics module via an outside of the electronics section. In addition or alternatively, the contacting element can be designed as a pin, pad, or conductor path structure, or a combination of at least two of the mentioned designs. A pad can be understood to mean, for example, a contact surface and/or elevation, which allows contacting not only via a point-shaped contact site but, for better electrical contacting, via a flat contact site. Additionally or alternatively, the contacting element can be embedded at least in sections in a material of the electronics section. As a result, various electrical or electronic components can be integrated into the ventricular assist device with relatively low manufacturing effort.

Furthermore, the electronics section can have a recess for accommodating at least one section of the pump motor. A recess can generally be understood to mean a pocket. For example, the recess can be formed so as to accommodate the pump motor in a precise fit. This embodiment allows the design of the electronics module to be kept particularly compact in the longitudinal direction.

According to one embodiment, the contacting element can extend into the recess in order to allow electrical contacting of the pump motor accommodated by the recess. In this case, the coupling section can extend around the recess, e.g., annularly, so that it is possible to guide the pump motor through the coupling section into the recess. This embodiment allows a particularly simple electrical contacting of the pump motor without additional contacting elements.

It is also advantageous if the electronics section has a sensor section for accommodating at least one sensor element and/or a connection section for connecting a cable to the electronics module. The contacting element can be arranged or arrangeable on the sensor section and/or on the connection section. The sensor section can be a flattened region of a lateral surface of the electronics section, for example. A connection section can be understood to mean, for example, a front side of the electronics module. For example, the connection section can be realized as a connection field with a plurality of contacting elements in the form of connector pins or contact grooves for contacting a cable or a plug connector. This allows easy attachment of sensor elements and easy electrical contacting of the electronics module.

According to one embodiment, the connection section can be arranged on a front side of the electronics section facing away from the coupling section. Additionally or alternatively, the electronics section can be coupled or couplable with a protective cap, a strain relief element, a bend protection element, or a combination of at least two of the aforementioned elements. This prevents damage to the electronics module. In addition, this makes it possible to easily insert the electronics module into the blood vessel.

According to another embodiment, the connection section can be formed with a plurality of contact grooves for electrically contacting the cable. A contact groove can be understood to mean, for example, a semi-circular depression which can be lined with an electrically conductive material. The contact grooves can, for example, be arranged around a central axis of the electronics section. This allows plug-free electrical contacting of the electronics module, e.g., by soldering individual wires of the cable to the electrically conductive material in the contact grooves.

The approach presented here also creates a ventricular assist device with the following features:

•

• a motor housing for accommodating a pump motor; and • an electronics module with an electronics section and a coupling section for accommodating at least one electronic component and/or at least one electrically conductive contacting element, wherein the electronics section and the coupling section or the motor housing are combined with one another to form a fluid-tight module housing to be arranged in a blood vessel, wherein the electronics section is fluid-tightly coupled with the motor housing via the coupling section.

Lastly, the presented approach creates a method for producing an electronics module for a ventricular assist device, wherein the ventricular assist device has a motor housing for accommodating a pump motor, wherein the method comprises the following steps:

•

• forming an electronics section for accommodating at least one electronic component and/or at least one electrically conductive contacting element on a coupling section, wherein the coupling section is formed in order to couple the electronics module fluid-tightly with the motor housing.

Furthermore, in a particularly favorable embodiment, an optional step of combining the electronics section with a coupling section designed as a separate element can be combined to form a fluid-tight module housing to be arranged in a blood vessel in order to couple the electronics module fluid-tightly with the motor housing.

The optional separate element can be formed as a coupling section by sintering, for example. In particular, the coupling section can be sintered directly to the electronics section in the step of combining. The electronics section can be formed, for example, in an additive manufacturing process, in particular by stacking ceramic layers one on top of the other. Alternatively, the electronics section can be formed in an injection-molding process or a machining process, e.g., by milling or turning. In the step of forming, the contacting element can be embedded directly into the electronics section, e.g., in the form of a pin for throughplating individual layers of the electronics section. Additionally or alternatively, the contacting element can be applied to a surface of the electronics section or individual layers thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

Advantageous exemplary embodiments of the invention are explained in more detail in the following description with reference to the drawings.

The figures show:

FIG. 1 a schematic illustration of a ventricular assist device according to an exemplary embodiment;

FIG. 2 A a schematic illustration of an electronics module of FIG. 1 ;

FIG. 2 B a schematic illustration of an electronics module for direct connection to the motor housing, e.g., by adhesive bonding;

FIG. 3 a schematic illustration of a layer construction of an electronics section according to an exemplary embodiment;

FIG. 4 a schematic illustration of an electronics module according to an exemplary embodiment;

FIG. 5 a schematic illustration of an electronics module of FIG. 4 ;

FIG. 6 a schematic illustration of an electronics module according to an exemplary embodiment;

FIG. 7 a flow diagram of a method for producing an electronics module according to an exemplary embodiment.

DETAILED DESCRIPTION

In the following description of favorable exemplary embodiments of the present invention, the same or similar reference signs are used for the elements which are shown in the various figures and have a similar effect, wherein a repeated description of these elements is omitted.

FIG. 1 shows a schematic illustration of a ventricular assist device 100 according to an exemplary embodiment. The ventricular assist device 100 , here by way of example a left ventricular ventricular assist device for percutaneous implantation into a left heart chamber, has an electronics module 102 which is fluid-tightly connected to a motor housing 104 for accommodating a pump motor. The electronics module 102 represents a proximal end of the ventricular assist device 100 and forms a transition between the motor housing 104 and a connection cable 106 for connecting the ventricular assist device 100 to an external energy source or an external evaluation or control device.

The ventricular assist device 100 has a cylindrical, elongated structure with a substantially constant outer diameter and rounded, tapered ends for easy positioning by means of a catheter in a blood vessel, e.g., the left heart chamber or the aorta.

By way of example, the ventricular assist device 100 has a tip in the form of a sensor assembly 110 , e.g., for pressure measurement.

FIG. 2 A shows a schematic illustration of the electronics module 102 of FIG. 1 . The electronics module 102 comprises a cylindrical module housing, which is composed of an (optional) coupling section 202 and an electronics section 204 . The (optional) coupling section 202 is used for fluid-tight coupling of the electronics module 102 with the motor housing, e.g., by welding. For adhesive bonds, direct joining can also take place. According to a favorable exemplary embodiment, the coupling section 202 is realized as a (metal) ring, in particular as a titanium ring. The electronics section 204 is used to accommodate one or more electronic components 206 . In addition, the electronics section 204 according to this exemplary embodiment has a plurality of electrically conductive contacting elements 208 , which are designed for the electrical contacting of the electronic component 206 or of the pump motor or for connecting a cable to the electronics section 204 .

The two sections 202 , 204 (insofar as the coupling section 202 is formed as a separate element) are, for example, fluid-tightly connected to one another by means of an adhesive bond. Alternatively, the motor housing can also be directly mounted on a surface portion of the electronics section 204 acting as coupling section 202 and can be fluid-tightly closed therewith.

According to FIG. 2 A , a portion of the contacting elements 208 is arranged on a front-side connection section 210 of the electronics section 204 facing away from the coupling section 202 and/or the motor housing side, wherein ends of the contacting elements 208 projecting from the connection section 210 are designed as connector pins for connecting a connection cable. The connection cable is accordingly contacted via contact sleeves or a direct connection. The connection section 210 can also be referred to as a connection field. The electronic component 206 , here a sensor element, is positioned on an external sensor section 212 of the electronics section 204 . The sensor section 212 is in this case realized as a flattening of a lateral surface of the electronics section 204 and thus forms a platform for the sensor element 206 . Several of the contacting elements 208 for contacting are also arranged in the sensor section 212 in a hermetic interior of the electronics section 204 .

The electronics module 102 , which can also be referred to as the backend of the ventricular assist device, is realized, for example, with a ceramic part as electronics section 204 and a sintered-on titanium ring as coupling section 202 . The two-part construction is advantageous because it simplifies subsequent production steps, such as hermetic welding of the electronics module 102 to the motor housing. The use of ceramics as a housing material first and foremost offers the advantage of a simple integration of complex conductor structures. On the other hand, by using a titanium element as coupling section 202 , hermetic welding to the motor housing is ensured.

The electronics section 204 is realized, for example, as a functionalized ceramic component by a layer-by-layer construction according to cofiring technology.

According to an exemplary embodiment, the coupling section 202 is glazed in a form-fitting manner in order to produce a hermetically sealed connection between the coupling section 202 and the electronics section 204 .

The electronics section 204 is optionally formed with one or more rounded steps 214 so that, for example, a thin-film substrate for connecting further sensors from the sensor assembly shown in FIG. 1 can be guided without damage to the connection section 210 . The connection section 210 serves, for example, to connect hermetic feedthrough pins to the connection cable.

Optionally, a further stage 216 is formed at least in sections around the connection section 210 in order to make connecting a protective cap, strain relief, or bend protection grommet possible.

FIG. 2 B shows a schematic illustration of an electronics module 102 according to another exemplary embodiment for direct connection to the motor housing, e.g., by adhesive bonding.

Here, it can be seen that the electronics module 102 has a coupling section 202 , which is formed as a surface layer or as a partial section of the electronics section 204 but not as a separate element as shown in FIG. 2 A .

FIG. 3 shows a schematic illustration of a layer construction of an electronics section 204 according to an exemplary embodiment. Shown by way of example is a layer construction of the electronics section 204 as can be realized in an LTCC process (LTCC=Low Temperature Cofired Ceramics). As can be seen, the layer construction comprises a plurality of individual layers 304 stacked one on top of the other along a longitudinal axis 300 of the electronics section 204 , in this case a plurality of disk-shaped ceramic layers.

Conductor structures of the contacting elements 208 are realized, for example, in the plane of the individual layers 304 by screen printing and vias from individual layer to individual layer.

The electronics module is constructed, for example, step by step by stacking stamped and conductively printed green parts. This results in the boundary condition that higher layers may have only identical or smaller dimensions than lower layers. Different form requirements can be realized, for example, by a corresponding post-processing of sintered parts of the electronics module by milling or turning.

Alternatively, the electronics section 204 is produced as a functionalized ceramic component by 3D printing, injection molding, or milling. The electrical functionalization is then carried out by screen printing, dispensing, and glazed feedthroughs.

FIG. 4 shows a schematic illustration of an electronics module 102 according to an exemplary embodiment. An embodiment of the electronics module 102 as a ceramic MID part is shown. In contrast to the electronics module described above with reference to FIGS. 1 to 3 , the lateral surface of the electronics section 204 in this case comprises a first cavity 400 , into which, by way of example, two contacting elements 208 extend, and a second cavity 402 , the bottom surface of which forms the sensor section for arranging the component 206 . In a third, front-side cavity 404 , the contacting elements 208 of the connection section 210 are arranged, wherein a bottom surface of the third cavity 404 forms the connection section 210 . Optionally, the electronics section 204 is conical in the region of the connection section 210 .

Due to the aforementioned manufacturing processes, form fits can be produced in a limited scope without post-processing so that in addition to platforms for sensors, cavities can also be realized on the lateral surface or front surface of the electronics section 204 as shown by way of example in FIG. 4 . The mechanical protection of the external sensor element 206 and of the connection section 210 can thereby be improved, for example.

FIG. 5 shows a schematic illustration of the electronics module 102 of FIG. 4 . An interior view of the electronics module 102 with exemplary conductor structures is shown. It can be seen that the electronics section 204 has an internal recess 500 into which a plurality of the contacting elements 208 extend. The recess 500 is used, for example, for accommodating a connection side of the pump motor in order to allow direct electrical contacting of the pump motor with the contacting elements 208 . In this case, it is useful if the coupling section 202 is realized as a ring.

The electrical conductor structures formed by the contacting elements 208 are produced, for example, externally by screen printing or internally by dispensing. FIG. 5 shows a corresponding exemplary embodiment. During dispensing, a robot arm guides a thin cannula by means of which conductive material, such as gold paste or conductive adhesive, is dispensed. The conductive paste is firmly connected to the ceramic by a sintering process in order to realize the electrical conductor paths.

The sensor element 206 is realized according to one exemplary embodiment as a sensor hub, e.g., in the form of a microcontroller, in order to detect calibration and identification information of the pump motor or of sensors. In this case, the sensor element 206 can be read, for example, via a communication bus in the connection cable by a central control device of the ventricular assist device. As a result, the control device can be parameterized with motor data, for example.

The sensor element 206 is designed, for example, to preprocess, e.g., to aggregate, filter, or calibrate, sensor data of sensors of the pump motor, or as transceiver to translate a communication protocol of the sensors into a more robust communication protocol or to add artificial redundancy or checksums.

FIG. 6 shows a schematic illustration of an electronics module 102 according to an exemplary embodiment. The electronics module 102 substantially corresponds to the electronics module described above with reference to FIG. 2 , with the difference that the connection section 210 has a plurality of arcuate contact grooves 600 , arranged, for example, concentrically to a peripheral line of the electronics section 204 , for electrically contacting the connection cable, e.g., individual wires of the connection cable. The contacting elements 208 each have an electrically conductive contacting surface 602 , which each line one of the contact grooves 600 .

The contact grooves 600 are used in particular for direct contacting of the connection cable to the ceramic. The strands of the connection cable are in this case contacted directly electrically to the externally positioned contact grooves 600 in the ceramic. A thin-film substrate is, for example, connected to the contact grooves 600 by blind pins or contact pads in the middle of the connection section 210 and by a short connection line. In order to prevent delamination of the mechanically stressed contacting surfaces 602 , an insulating ceramic ring is, for example, pushed over the connection section 210 for mechanical stabilization.

FIG. 7 shows a flow diagram as method 700 for producing an electronics module according to an exemplary embodiment. In a first step 710 , the electronics section for accommodating at least one electronic component and/or at least one electrically conductive contacting element is formed on a coupling section, wherein the coupling section is formed in order to couple the electronics module fluid-tightly with the motor housing. In a second step 720 , the electronics section can be combined with the coupling section in order to produce the hermetically sealed module housing.

According to an exemplary embodiment, the combining in step 720 takes place by sintering the coupling section onto the electronics section. Alternatively, the combining takes place by joining the coupling section and the electronics section. Alternatively, the coupling element can be made of metal, in particular titanium film, and the combination step 720 can take place on the diffusion welding of the film-shaped coupling element to the electronics element. The coupling element can also be designed as a metallic surface coating of the electronics element so that the hermetic joining to the motor housing is subsequently made possible by, for example, a laser soldering process.

According to another exemplary embodiment, the electronics section is produced layer by layer as a ceramic component in step 710 .

The hermetic module housing can be joined to the motor housing by welding an optional coupling element, e.g., made of titanium. In another embodiment, the joining can take place by reactive bonding of the motor housing (e.g., made of titanium) to the module housing (e.g., made of oxide ceramics). Alternatively, it is, for example, possible to join the electronics section to the motor housing by adhesively bonding to an artificial resin, for example.

If an exemplary embodiment includes an “and/or” conjunction between a first feature and a second feature, this should be read to mean that the exemplary embodiment according to one embodiment comprises both the first feature and the second feature, and according to another embodiment comprises either only the first feature or only the second feature.

In summary, the following features of the invention should in particular be noted:

The invention relates to an electronics module ( 102 ) for a ventricular assist device, wherein the ventricular assist device has a motor housing for accommodating a pump motor. The electronics module ( 102 ) comprises an electronics section ( 204 ) for accommodating at least one electronic component ( 206 ) and/or at least one electrically conductive contacting element ( 208 ), and a coupling section ( 202 ) designed as a joint between the motor housing ( 104 ) and the electronics section ( 204 ) or as a separate component to be joined, wherein the motor housing ( 104 ) and the electronics section ( 204 ) are combined or can be combined via the coupling section ( 202 ) with one another to form a fluid-tight module housing ( 104 ) to be arranged in a blood vessel.

The invention in particular relates to the aspects specified in the following clauses:

•

• 1. Electronics module ( 102 ) for a ventricular assist device ( 100 ), wherein the ventricular assist device ( 100 ) has a motor housing ( 104 ) for accommodating a pump motor, wherein the electronics module ( 102 ) has the following features:

• an electronics section ( 204 ) for accommodating at least one electronic component ( 206 ) and/or at least one electrically conductive contacting element ( 208 ); and • a coupling section ( 202 ), which is designed as a joint between the motor housing ( 104 ) and the electronics section ( 204 ) or as a separate component to be joined, wherein the motor housing ( 104 ) and the electronics section ( 204 ) are combined or can be combined via the coupling section ( 202 ) with one another to form a fluid-tight module housing ( 104 ) to be arranged in a blood vessel. • 2. Electronics module ( 102 ) according to Aspect 1, in which the coupling section ( 202 ) is realized as a separate element, in particular as a titanium element and/or a sintered element, and/or the electronics section ( 204 ) is realized as a ceramic element and/or a layer composite of at least two layers ( 304 ). • 3. Electronics module ( 102 ) according to Aspect 2, in which the layers ( 304 ) are stacked one on top of the other in the longitudinal direction of the electronics section ( 204 ). • 4. Electronics module ( 102 ) according to Aspect 1, wherein the coupling section ( 202 ) is formed as a surface layer or a partial section of the electronics section ( 204 ) and/or wherein the electronics module ( 102 ) is directly connectable or connected, in particular adhesively bonded, to the motor housing ( 104 ). • 5. Electronics module ( 102 ) according to one of the preceding aspects, in which the coupling section ( 202 ) is welded or can be welded to the motor housing ( 104 ). • 6. Electronics module ( 102 ) according to one of the preceding aspects, in which the coupling section ( 202 ) is annular. • 7. Electronics module ( 102 ) according to one of the preceding aspects, in which the coupling section ( 202 ) and/or the electronics section ( 204 ) is cylindrical. • 8. Electronics module ( 102 ) according to one of the preceding aspects, with the electronic component ( 206 ) and/or the contacting element ( 208 ), wherein the contacting element ( 208 ) is designed to allow electrically conductive contacting of the electronics module ( 102 ) via an outside of the electronics section ( 204 ), and/or is designed as a pin and/or pad and/or conductor path structure and/or is embedded, at least in sections, in a material of the electronics section ( 204 ). • 9. Electronics module ( 102 ) according to one of the preceding aspects, in which the electronics section ( 204 ) has a recess ( 500 ) for accommodating at least one section of the pump motor. • 10. Electronics module ( 102 ) according to Aspect 8 and 9, in which the contacting element ( 208 ) extends into the recess ( 500 ) in order to allow electrical contacting of the pump motor accommodated by the recess ( 500 ). • 11. Electronics module ( 102 ) according to Aspect 8 or 10, in which the electronics section ( 204 ) has a sensor section ( 212 ) for accommodating at least one sensor element ( 206 ) and/or a connection section ( 210 ) for connecting a cable ( 106 ) to the electronics module ( 102 ), wherein the contacting element ( 208 ) is arranged or can be arranged on the sensor section ( 212 ) and/or on the connection section ( 210 ). • 12. Electronics module ( 102 ) according to Aspect 11, in which the connection section ( 210 ) is arranged on a front side of the electronics section ( 204 ) facing away from the coupling section ( 202 ) and/or is coupled or can be coupled with a protective cap and/or a strain relief element and/or a bend protection element. • 13. Electronics module ( 102 ) according to Aspect 11 or 12, in which the connection section ( 210 ) is formed with a plurality of contact grooves ( 600 ) for electrically contacting the cable ( 106 ). • 14. Ventricular assist device ( 100 ) with the following features:

• a motor housing ( 104 ) for accommodating a pump motor; and • an electronics module ( 102 ) according to one of the preceding claims. • 15. Method ( 700 ) for producing an electronics module ( 102 ) for a ventricular assist device ( 100 ), wherein the ventricular assist device ( 100 ) has a motor housing ( 104 ) for accommodating a pump motor, wherein the method ( 700 ) comprises the following step:

• forming ( 710 ) an electronics section ( 204 ) for accommodating at least one electronic component ( 206 ) and/or at least one electrically conductive contacting element ( 208 ) on a coupling section ( 202 ), wherein the coupling section ( 202 ) is formed in order to couple the electronics module ( 102 ) fluid-tightly with the motor housing ( 104 ).